Communication system with multi-dimensional rate adaptation

ABSTRACT

Performing wireless transmission of data over a wireless communication medium. A first data structure may be maintained which includes data rate information for transmission using a first number of streams. A second data structure may be maintained which includes data rate information for transmission using a second number of streams. Channel characteristics of the wireless communication medium may be determined. Channel characteristic information may be maintained based on the determined channel characteristics. Accordingly, a stream configuration and data rate may be determined based on the current channel characteristic information. Wireless transmission may be performed using the determined stream configuration and data rate. Determining channel characteristics, maintaining current channel characteristic information, determining a stream configuration and data rate, and performing wireless transmission may be dynamically performed a plurality of times during wireless data transmission.

FIELD OF THE INVENTION

The present invention relates generally to wireless communication, andmore particularly to a rate adaptation scheme for a multiple in multipleout (MIMO) transmission system that can accommodate differenttransmission rates for a first number of spatial streams and a secondnumber of spatial streams.

DESCRIPTION OF THE RELATED ART

Wireless communication is being used for a plethora of applications,such as in laptops, cell phones, and other wireless communicationdevices or mobile devices (collectively referred to as “wirelessdevices”). Some wireless devices in the prior art are capable ofperforming rate adaptation, i.e., transmitting signals at differenttransmission rates, e.g., depending on the characteristics of thechannel. For example, if the communication channel is noisy, thewireless device may transmit signals at a lower communication rate andpossibly with additional error correction. If the communication channelis relatively clear, the wireless device may transmit signals at ahigher communication rate and possibly with less error correction.

Some wireless devices that employ MIMO are also capable of selectivelytransmitting using different spatial stream configurations, e.g.,transmitting using one or more streams of data. In other words, somewireless devices are capable of transmitting either a single spatialstream of data or multiple spatial streams of data. However, prior artwireless devices have only been able to perform rate adaptation for onerespective stream configuration. For example, prior art wireless deviceshave only been able to perform rate adaptation for single stream rates,or have only been able to perform rate adaptation for dual stream rates,but not both, e.g., in overlapping configurations.

Therefore, improvements in rate adaptation are desired for wirelessdevices that are capable of transmitting at different rates usingdifferent stream configurations.

SUMMARY OF THE INVENTION

Various embodiments are presented of a system and method for performingwireless communication using rate adaptation for different datarate/stream configurations.

The wireless device maintains one or more data structures comprisingdata rate information for different stream configurations. For example,the wireless device may maintain a first data structure comprising datarate information for a first number of streams (e.g., single streamtransmission) and a second data structure comprising data rateinformation for a second number of streams (e.g., multiple stream (e.g.,dual stream) transmission).

The wireless device may be configured to determine channelcharacteristics of the wireless communication medium. For example, thewireless device may determine the strength of the wireless communicationmedium, e.g., whether the medium is noisy or clear.

Based on the determined channel characteristics, the wireless device maybe configured to maintain current channel characteristic information.For example, the wireless device may be configured to maintaininformation regarding various parameters of the wireless communicationmedium, such as packet error rate (PER), received signal strengthindications (RSSI), failed acknowledgements, etc.

The wireless device may then be configured to determine a streamconfiguration and data rate based on the current channel characteristicinformation, e.g., using the first and/or second data structuredescribed above, among other possibilities. Thus, the wireless devicemay be configured to determine a stream configuration, e.g., singlestream transmission, dual stream transmission, etc., and also determinea transmission rate for the selected stream configuration, e.g., thatprovides improved communications based on the current characteristics ofthe channel.

Once the wireless device determines the appropriate stream configurationand data rate, the device may read into or use the respective datastructure to determine the appropriate data rate/stream configurationparameters to achieve the desired data rate and stream configuration.The wireless device may then perform wireless transmission using thedetermined stream configuration and data rate.

The wireless device is configured to dynamically perform the abovemethod during data transmission, and thus the wireless device may adjustits stream configuration and data rate dynamically based on currentchannel characteristics. In other words, the wireless device may selectthe appropriate data rate/stream configuration based on current channelcharacteristics. Thus, the wireless device may iteratively determinechannel characteristics, maintain current channel characteristicinformation, determine a stream configuration and data rate, and performwireless transmission a plurality of times during wireless datatransmission. The wireless device may dynamically utilize differentstream configurations and/or transmission rates as appropriate,dependent on current channel characteristics.

BRIEF DESCRIPTION OF THE DRAWINGS

A better understanding of the present invention can be obtained when thefollowing detailed description of the preferred embodiment is consideredin conjunction with the following drawings, in which:

FIG. 1 illustrates exemplary wireless devices performing wirelesscommunication, according to one embodiment;

FIG. 2 is an exemplary block diagram of a wireless device of FIG. 1,according to one embodiment;

FIG. 3 is a flowchart diagram illustrating one embodiment of a methodfor determining a single stream or multiple stream configuration forwireless communication;

FIG. 4 illustrates an exemplary data structure containing rateinformation for single stream transmission, according to one embodiment;and

FIGS. 5-7B are flowchart diagrams illustrating various specificembodiments of a method for determining a single stream or multiplestream configuration for wireless communication.

While the invention is susceptible to various modifications andalternative forms, specific embodiments thereof are shown by way ofexample in the drawings and are herein described in detail. It should beunderstood, however, that the drawings and detailed description theretoare not intended to limit the invention to the particular formdisclosed, but on the contrary, the intention is to cover allmodifications, equivalents and alternatives falling within the spiritand scope of the present invention as defined by the appended claims.

DETAILED DESCRIPTION OF THE EMBODIMENTS

FIG. 1—Exemplary Wireless System

FIG. 1 illustrates an exemplary wireless device 100 wirelessly coupledto wireless devices 125 and 150, according to one embodiment. As shownin FIG. 1, the wireless device 100 may be a router and the wirelessdevices 125 and 150 may be a laptop or cell phone (or smart phone orother mobile device). However, it should be noted that other wirelessdevices are envisioned (for the wireless devices 100, 125, and 150),such as personal digital assistants, multimedia players (portable orstationary), routers, and/or other mobile devices/computing systemswhich are operable to use wireless communication.

During wireless communication, the wireless device 100, 125, and/or 150may perform various procedures to determine an efficient wirelesscommunication mode. For example, one or more of the wireless devices maydetermine an efficient wireless communication method, which may includea single stream or dual stream configuration (among other multiplestream configurations), a particular data rate, and/or a particularmodulation and encoding, among other possibilities. In some embodiments,this determination may be largely or solely carried out by the wirelessdevice 100. The determination of this wireless communication mode isdescribed in further detail below.

Note that the wireless devices may communicate using various protocols,such as, for example, wireless local area network (WLAN), Bluetooth,and/or other communication protocols, as desired.

FIG. 2—Exemplary Block Diagram of the Wireless Device

As shown in FIG. 2, the wireless devices 100, 125, and/or 150 mayinclude various circuitry. However, for convenience, only the wirelessdevice 100 is described below, although these descriptions may apply towireless devices 125 and 150.

In one embodiment, the wireless device 100 may include host circuitry202 (including host memory 204, memory controller bridge 206, CPU 208,and/or other circuitry). The host circuitry 202 may be used forperforming various functions of the device, e.g., cellular functions fora cell phone.

As also shown, the wireless device 100 may include a network card orcircuitry 210. The network card 210 may be coupled to the host circuitry202 via various busses, such as PCI, PCIe, ISA, etc. The network card210 may include MAC 214, which may include HIU (High speed InterfaceUnit) 216, DMA (direct memory access) 218, and/or PCU (Protocol ControlUnit) 220. The MAC 214 may be coupled to baseband (BB) 222, which may bein turn coupled to a plurality of digital to analog converters (DACs)224. These DACs may provide analog output to radio chip 226 which mayprovide analog signals to other wireless devices (e.g., 125 and/or 150)via antennae 228. Similarly, the ADCs 225 may receive analog signalsfrom radio chip 226 (via antennae 228) and convert them to digitalsignals for provision to BB 220.

Note that while the above descriptions (and the illustration of FIG. 2)show host circuitry coupled to a network card, other embodiments areenvisioned. For example, the host circuitry and network circuitry may becollocated and may not be separated and coupled over a bus as shown inthe Figure. More specifically, in one embodiment, the wireless device100 may include integrated network circuitry.

Additionally, as indicated above, the wireless device 100 may includeone or more memory mediums and processors (e.g., including the CPU 208and host memory 204) for implementing various functionality. Forexample, in one embodiment, the wireless device 100 may include programinstructions stored on the memory medium which may be executable by theprocessor to perform the functionality or methods described herein. Inone embodiment, software of the wireless device 100 (e.g., programinstruction stored on a memory medium, that may be executed by aprocessor) may perform determinations or modifications of currenttransmission configurations (e.g., as described in the flowcharts below)and hardware of the wireless device 100 may perform actual transmissionsof the packets according to the determinations by software.Additionally, in some embodiments, the hardware may further include theability to automatically attempt lower data rate/stream configurationwhen packets of higher data rate/stream configurations fail. Informationregarding transmitted packets or attempted transmitted packets may thenbe provided back to the software for future determinations andadaptations, as described below.

It should be noted that the above described system diagram is exemplaryonly and that various modifications, additional components, removedcomponents, alternate configurations, etc. are envisioned.

FIG. 3—Method for Determining a Configuration for Wireless Communication

FIG. 3 is a block diagram illustrating one embodiment of a method fordetermining stream configurations for wireless communication. Asindicated above, the wireless transceiver may be included in variouswireless devices, such as a wireless router. The method shown in FIG. 3may be used in conjunction with any of the computer systems, devices, orcircuits shown in the above Figures, among other devices. In variousembodiments, some of the method elements shown may be performedconcurrently, performed in a different order than shown, or omitted.Additional method elements may also be performed as desired. As shown,this method may operate as follows.

In 302, a first data structure may be maintained that may include datarate information for a first number of streams (e.g., for single streamtransmissions). In some embodiments, the first number of streams may bepartial streams, e.g., in a MIMO system. As shown in an exemplary datastructure of FIG. 4, the first data structure may include PHY throughputinformation, data rate/stream configuration information (also sometimesreferred to as modulation coding schemes MCSs), received signal strengthindicator information (RSSI), and packet error rate (PER) information.The PHY throughput information may be a value, e.g., 1 Mbps, 2 Mbps, 5.5Mbps, 11 Mbps, 13 Mbps, . . . 300 Mbps, etc. The data rate/streamconfiguration information may include rate information and encodinginformation. As shown, the data rate/stream configuration informationmay include 1 Mbps, CCK; 2 Mbps, CCK; 5.5 Mbps, CCK; 11 Mbps, CCK; MCS0,SS, full-GI, HT40 (e.g., for a single stream data structure); . . . ;MCS15, DS, half-GI, HT40 (e.g., for a dual stream data structure, suchas the second data structure below). Note that HT40 refers to highthroughput, 40 MHz; MCS0 and MCS15 refer to various known modulationcoding schemes described in the 802.11n specification, and GI refers toguard interval. The data rate/stream configuration may include theparticular data rate, as well as stream configuration, used to achieve agiven PHY throughput.

In one embodiment, the information in the PHY throughput, DataRate/Stream Configuration, and RSSI threshold values are static, whilethe PER information in the rightmost column is dynamically adjustedduring operation. A single RSSI value (not shown) may also be maintained(e.g., in the first data structure or a separate data structure) and maybe dynamically adjusted. Alternatively, a separate RSSI value ismaintained for each PHY Throughput value. In one embodiment, separatetables are maintained for the static and dynamic values.

The RSSI information may include RSSI threshold for respective datarates/stream configurations and, similarly, the PER information (e.g.,maximum PER values for a given data rate/stream configuration) may beassociated with each rate. For example, as shown, for 1 Mbps, the RSSIthreshold may be 4 dB and the PER cap may be 5%. Similarly, for 2 Mbps,the RSSI threshold may be 6 dB and the PER cap may be 6%; for 5.5 Mbps,the RSSI threshold may be 7 dB and the PER cap may be 10%; for 11 Mbps,the RSSI threshold may be 10 dB and the PER cap may be 20%; . . . ; andfor 300 Mbps, the RSSI threshold may be 24 dB and the PER may be 55%.Thus, in one embodiment, a rate may only be used when the current RSSIis less than the threshold value and the current PER is less than thePER cap in the table. Additionally, note that the above described tableis exemplary only and other table formats, information, etc. areenvisioned.

In 304, a second data structure may be maintained that may include datarate information for a second number of streams (e.g., for dual streamtransmissions). The second number of streams may be spatial streams,e.g., in a MIMO system. The second data structure may be similar to thefirst data structure described above, except related to the data rateinformation for the second number of streams. However, it should benoted that the first and second data structures may compose or be storedin a single data structure, or may be spread among a plurality of datastreams (e.g., with static tables for each number of streams and dynamicvalues for each number of streams), as desired.

In 306, channel characteristics of a wireless communication medium maybe determined. For example, the determined channel characteristics mayinclude a packet error rate (PER), received signal strength indicator(RSSI), acknowledgement information, and/or other information.

In one embodiment, the channel characteristics may be determined bysending probe transmissions using various data rates and streamconfigurations. The probe transmissions may simply be one or moretransmissions of packets, e.g., sending a plurality of packets, such asthree packets at a particular data rate and stream configuration. In oneembodiment, the probe transmission may be a single transmission of ajumbo packet, which may include a plurality of concatenated packets.This may be particularly useful for getting PER information for a singletransmission. However, the probe transmissions may simply be normallytransmitted packets, on which information is gathered. In someembodiments, every transmission may be considered a probe transmission.In other words, determining channel characteristics may be performed forevery attempted transmission of packets (e.g., including those thatfail). Further exemplary details regarding determining the currentchannel characteristics are provided below with respect to the followingFigures.

In 308, current channel characteristic information may be maintainedbased on the determined channel characteristics of 306. In oneembodiment, the current channel characteristic information may includePER information, RSSI information, acknowledgement information, and/orother information (e.g., at various data rates/stream configurations),e.g., determined in 306. Further exemplary details regarding maintainingchannel characteristic information are provided below with respect tothe following Figures.

In 310, a stream configuration and data rate may be determined based onthe current channel characteristic information. The stream configurationand data rate may be determined using the first data structure and/orthe second data structure. In other words, based on the current channelcharacteristic information, the method may include determining thestream configuration and data rate by comparing the currentcharacteristic information to thresholds (e.g., the RSSI threshold inthe data structures) and determining the highest data rate or data rateand stream configuration that can be used or sustained. As describedbelow, the PER may be used to compute the throughput.

In 312, wireless transmission may be performed using the determinedstream configuration. In other words, packets may be transmittedwirelessly using the determined data rate/stream configuration.

The method may include performing one or more of 302-312 (and morespecifically, 306-312) a plurality of times in a dynamic fashion duringwireless data transmission. In other words, the wireless device mayselect the appropriate data rate/stream configuration based on currentchannel characteristics. Thus, the wireless device may iterativelydetermine channel characteristics, maintain current channelcharacteristic information, determine a stream configuration and datarate, and perform wireless transmission a plurality of times duringwireless data transmission. The wireless device may dynamically utilizedifferent stream configurations and/or transmission rates asappropriate, dependent on current channel characteristics. Note that themethod described above may be performed in a periodic fashion, e.g.,based on numbers of packets sent, numbers of milliseconds, etc. In oneembodiment, the stream configuration and data rate may be determinedbased on channel characteristics every 5-10 milliseconds.

As indicated above, the method of FIG. 3 may be performed by any ofvarious wireless devices. In some embodiments, where two wirelessdevices are communicating, one of the devices may perform the method andcommunicate determined communication configuration (e.g., including datarate/stream configuration) to the other wireless device. However, eachdevice may perform the method simultaneously and independently in orderto determine its own maximum transmission data rate/streamconfiguration.

Additionally, while present embodiments are described regarding a firstnumber of streams and a second number of streams, the method can beexpanded to n number of stream configurations (e.g., between a singlestream, a dual stream, or a triple stream configuration, among variouspossibilities of stream configurations). Thus, the method can beexpanded to rate adaptation among n different stream configurations.

FIGS. 5-7B—Method for Determining a Configuration for WirelessCommunication

FIGS. 5, 6A, 6B, 7A, and 7B are flowcharts of specific embodiments fordetermining a configuration for wireless communication. Note that theseflowcharts are provided as examples only and are not intended to limitthe scope of various descriptions herein (e.g., the method of FIG. 3,described above). Additionally note that data rate/stream configurationmay also be referred to as “DRSC” in the following descriptions.

FIG. 5 illustrates a broad method of operation for a wireless deviceperforming wireless communication. In some embodiments, this method maybe performed for every transmitted packet (e.g., successful orunsuccessful).

As shown, in 502, a packet may be transmitted. The packet may be atypical packet or a jumbo packet (e.g., including a plurality ofconcatenated packets). The packet may be sent at a specific datarate/stream configuration.

In 504, an acknowledgement may be received. The fact that theacknowledgement was received for the data rate/stream configuration maybe recorded. When the acknowledgement is not received or theacknowledgement indicates a failed transmission, the data rate/streamconfiguration may not be a viable transmission configuration, butadditional information (e.g., via probes) may be required to make acomplete determination for the data rate/stream configuration.

In 506, an RSSI for the packet may be determined or calculated.Similarly, in 508, a PER for the packet may be determined or calculated.

In 510, rcUpdate may be performed for the transmitted packet (or alltransmitted packets, e.g., since the last rcUpdate). It should be notedthat rcUpdate may be performed periodically (e.g., based on time, numberof transmitted packets, number of attempted transmissions, etc.) or foreach transmitted or attempted packet. Specific embodiments of rcUpdateare described below regarding FIGS. 7A and 7B.

In 512, rcFind may be performed to determine a data rate/streamconfiguration for the next packet. Specific embodiments of rcFind aredescribed below regarding FIGS. 6A and 6B.

FIGS. 6A and 6B

FIGS. 6A and 6B provides a method for determining the rate for the nexttransmission (rcFind) and FIGS. 7A and 7B provides a method for updatingPER statistics and probe intervals (rcUpdate). More specifically FIGS.6A and 7A each provide simple flow charts for rcFind and rcUpdate,respectively, and FIGS. 6B and 7B provide more explicit flow charts forrcFind and rcUpdate respectively. As indicated above, these flowchartsand descriptions are exemplary only and modifications and variations areenvisioned.

In 520 (of FIG. 6A), a lookup (lkup) or current RSSI is determined(e.g., of a transmitted packet, as in 506 above). In some embodiments,the lkup RSSI may be determined as the median RSSI of the last threeacknowledged transmitted packets. In 522, the RSSI value may be aged.The RSSI value may be aged according to the following formula (althoughothers are envisioned): do not reduce dB of RSSI value if the RSSI isless than 25 ms old, reduce by 10 dB if age is greater than 185 ms, andreduce linearly between 25 ms and 185 ms old.

In 524, a PER cap may be determined from the current PER value. In oneembodiment, if the current PER is less than or equal to 12%, the PER capmay be assigned to 12%, otherwise the PER cap may be assigned to thecurrent PER value.

In 526, the current stream configuration may be determined (e.g.,whether the current stream configuration is single stream (SS) or dualstream (DS)).

For SS, in 528, a rate may be determined that maximizes throughput basedon the current PER, e.g., using a single stream data structure.

In 530, it is determine whether a stream probe or rate probe should besent. If it is time, in 532, a probe type is determined, a probe issent, and the configuration may be adjusted (e.g., switching streams orconfigurations) to determine an data rate/stream configuration to use.However, if it is not time to send a probe, the determined datarate/stream configuration of 528 is used. The same procedure may beperformed for DS, except using a dual stream data structure for 538.Similarly, it may be determined in 540 whether it is time to send aprobe, and if so, appropriate measures may be taken in 542 (as in 532above).

Turning now to FIG. 6B, which provides more exemplary detail on thercFind procedure, in 602, it is determined whether a fixed rate,multicast, or broadcast is to be performed. If so, the data rate/streamconfiguration is correspondingly found in 638 (since rate adaptation maynot be necessary). If not, the method continues to 604.

In 604, the lookup (lkup) RSSI is assigned to the median RSSI of thelast n acknowledged packets, e.g., the last 3 acknowledged packets.

In 606, the lkup information is aged according to an aging procedure. Inthis case, the lkup information is not aged if it is less than 25 msold, is aged by 10 dB if the age is greater than 185 ms, and is agedaccordingly to a linear scale from 0 to 10 dB between 25 ms and 185 ms(although other scales are envisioned).

In 608, the PER cap is determined. More specifically, if the current PERis less than or equal to 12% (other values are envisioned), the PER capis set to 12% whereas it is set to the current PER if the PER is greaterthan 12%.

In 610, it is determined if the current stream configuration is equal toSS (single stream). In some embodiments, a variable “Stream_config” maybe used which can take either of two values, single stream and dualstream (although more than two types of streams are envisioned, asindicated above). For example, in one embodiment, the variable“Stream_config” can take three or more values, such as single stream,dual stream, three streams, etc.

If it is, in 612 all valid DRSC values in the SS stream DRSC table aretraversed. For each DRSC that has an RSSI threshold less than the LkupRSSI, the achievable UDP (user datagram protocol) throughput isestimated based on the PER cap determined in 608. Accordingly, thehighest UDP throughput is chosen from the available DRSC values. Forexample, if the lkup RSSI is 20 dB, but the DRSC is 25 dB, then anotherDRSC may need to be chosen (since the 20 dB is less than the thresholdRSSI of 25 dB). Thus, the highest UDP DRSC of the table may bedetermined by traversing through all the available rates and comparingthe lkup RSSI to the RSSI threshold using the current PER. Note that thePER cap may be different for different rates; accordingly, the DRSC withthe highest throughput (based on the PER) should be chosen. Throughputmay be calculated according to the following formula:throughput=(1−PER_cap)*the maximum throughput of the corresponding rate

In 614, if the determined DRSC (txDRSC) (from 612) is not greater thanthe current maximum SS DRSC, then the txDRSC is selected in 638.However, if it is, it is determined in 616 whether a probe for a higherSS DRSC (a rate probe) should be sent (e.g., based on a periodicschedule of probing, e.g., 100 ms, among other possibilities). If so, in622, the txDRSC is set to a value higher than the max SS DRSC (e.g., thenext highest value). At this point the DRSC is chosen in 638.

However, if a rate probe should not be sent, it is determined in 618whether it is time to send a stream probe. Note that a stream probe is aprobe used to test a stream configuration and a rate probe is used totest a particular rate within a stream configuration. If so, in 624, thelowest DS (dual stream) DRSC whose throughput is greater than thethroughput of the max SSCS is selected, the stream configuration isswitched, and probes may be sent (e.g., two consecutive successfulprobes, to ensure that the stream configuration should change). Itshould be noted that stream configuration changes may be treated moreconservatively than rate changes within a stream since changes within astream configuration typically have a high reliability fall backposition (e.g., the last properly used DRSC value) whereas a streamconfiguration change does not have such a fall back within that streamconfiguration. Thus, more than one probe may be required when switchingstream configurations to ensure that the alternate stream configurationand DRSC is valid and sustainable. Additionally, for similar reasons,stream configurations may only be switched when there is a large (incomparison to rate changes within the stream configuration) potentialthroughput differential between the current DRSC throughput and thepotential alternate stream configuration DRSC throughput.

Accordingly, the DRSC is found in 638. However, if it is not time tosend the probe, in 620, the txDRSC is set equal to the max SS DRSC, andthe DRSC is found in 638.

Turning back to the decision in 610, if the current stream configurationdoes not equal SS, all valid DRSC in the DS (dual stream) DRSC table aretraversed. For each DRSC in the DS data structure that has RSSIthreshold <Lkup RSSI, an achievable UDP throughput is estimated based onthe PER cap (see throughput formula above). Accordingly, the DRSC thatachieves the highest UDP throughput is selected.

In 626, it is determined if the currently selected DRSC (txDRSC) isgreater than the max DS DRSC. If it is not, the DRSC is found in 638 (astxDRSC). However, if it is, in 628, it is determined whether it is timeto send a probe at a higher DS DRSC (a DS rate probe).

If it is time to send a rate probe, one or more probes are sent at anDRSC one level higher (according to the DS data structure) than the maxDS DRSC in 634, and the DRSC is found in 638. However, if it is not timeto send a rate probe, it is determined in 630 if it is time to send astream probe. If not, in 632, the txDRSC is set equal to the max DSDRSC, and the DRSC is found in 638. If it is, in 636, the lowest SS DRSCwhose throughput is greater than the throughput of max DS DRSC isselected, the stream configuration is switched, and probes may be sentfor the new configuration (e.g., two consecutive probes). Accordingly,in 638, the DRSC is found.

Note that the maximum DRSC for dual stream and single stream may bemaintained separately. Additionally, as indicated above, PER caps andRSSI values may be maintained per DRSC per stream configuration. Inother words, PER caps and RSSI values may be different for every entryin both single stream and multiple stream data structures.

FIGS. 7A and 7B

As indicated above FIGS. 7A and 7B provide simple and more detailedexemplary flowcharts of the rcUpdate procedure referenced in 510 of FIG.5. As noted above, these are exemplary only and modifications andalternate methods are envisioned.

In 562 (of FIG. 7A), it is determined if excessive retries on thecurrent DRSC and possibly lower DRSC have occurred. More specifically,it is determined if transmissions of the current DRSC have failedexcessively (e.g., on an order of magnitude of 3, 5, 10, 20 failedpacket transmissions).

Accordingly, in 564, PER values of the current DRSC may be updated invarious data structures (e.g., the SS data structure or the DS datastructure) based on the determination of 562.

Where excessive retries have not occurred, in 566, it may be determinedif the current packets or DRSC value is part of a probe transmission(e.g., stream or rate probe).

In 568, data structures and/or the stream configuration may be updatedbased on 566 and/or the results of the probe. For example, if the DRSCvalue is part of a stream probe, and it was successful, the streamconfiguration may be changed to the probed DRSC. If not, the streamconfiguration may remain unchanged. Similarly, a successful rate probemay increase the rate in the current stream configuration to a highervalue for increased throughput. Where the current DRSC value/packets arenot probes (rate or stream), then maintenance of the data structures maybe performed, as described in more detail below.

Finally, in 570, DRSC states or values in the SS and/or DS datastructures may be aged.

Turning now to FIG. 7B, which provides more exemplary detail on thercUpdate procedure, in 640, it is determined if excessive retries haveoccurred with the current DRSC value, as described in 562 above.

In 642 if there are not excessive retries of the current DRSC, theTxDRSC PER is updated (e.g., in the current stream configuration's datastructure) according to the formula (PER=⅞*old_PER+⅛*new_PER) in 642.Thus, the current DRSC PER value may be updated with a bias for the oldPER values.

In 644, it is determined if TxDRSC is a stream probe. If it is, in 646,it is determined whether there is less than one retry (i.e., if thestream probe is successful). If not, the stream is not probed foranother 200 ms (in 654) and the stream configuration is switched in 656.Note that switching the stream configuration actually results in thestream configuration remaining the same since the previous transmission.This is due to the fact that when a stream probe is sent (e.g., fromrcFind, described above) the stream configuration is switched from acurrent stream configuration to an alternate stream configuration, andif the stream probe is unsuccessful (as determined in 646->656), thestream configuration is switched back to the current streamconfiguration (rather than the alternate stream configuration which justfailed).

Flow continues to 666, described in more detail below. If the TxDRSC hasless than one retry (from 646), in 648, the TxDRSC PER is set to avalue, e.g., 20, if the PER is greater than a threshold, e.g., 30%, theprobe interval is reduced by half, and the maxDRSC is set to the probeDRSC. Thus, since the first probe was successful, the data structure ofthe selected stream configuration is updated and the maxDRSC value forthe selected stream configuration is also updated. An additional probeis correspondingly sent out at faster rate.

Accordingly, in 650, it is determined if both probes have a less thanone retry (i.e., both successful); if they do, flow continues to 666,described below. However, if they do not, the stream configuration isswitched back to the previous stream configuration (as described above)in 652 and flow continues to 666.

Turning back to the determination that TxDRSC was not a stream probe (in644), if TxDRSC is a rate probe and less than one retry (in 658), in660, the TxDRSC PER is set to a value, e.g., 20, if PER is greater thana threshold, e.g., 30%, the probe interval is reduced by half, and themaxDRSC probe is set to the probe DRSC. Thus, the rate is updated upon asuccessful rate probe. Flow continues to 666.

Turning back to the determination of excessive retries in 640, if it hasoccurred, then in 643 the TxDRSC PER is incremented by 30 and it isensured that all higher DRSC PER's (in the corresponding data structure)are greater or equal to the TxDRSC PER. Thus, the current PER (which wasexcessively failed) is penalized, and all higher data rates arecorrespondingly penalized since higher rates cannot (or typically donot) have better transmission success than those below. Flow continuesto 662 joined by the pathway where the TxDRSC is not a rate probe withless than one retry (i.e., the rate probe failed).

In 662, it is determined if the TxDRSC PER is greater than 55% and isnot a stream or rate probe DRSC. If not, flow continues to 666; if so,in 664, the maxDRSC is set to the next lower DRSC and a probe is notsent for another 100 ms. Thus, in this case, the maxDRSC is penalizeddue to the high PER (greater than 55%). Flow from 664 also continues to666.

In 666, maintenance on the data structure corresponding to the streamconfiguration of the current DRSC is performed. More specifically, forconsistency, it is ensured that all DRSC above TxDRSC have a PER valuegreater than or equal to the current DRSC PER. It is also ensured thatall DRSC below TxDRSC have a PER value less than or equal to the currentDRSC PER.

In 668, all DRSC states are aged every 50 ms (the PER is reduced by afactor of ⅛). Aging the DRSC states (e.g., the PER values) may encouragethe wireless device to keep attempting higher transmission rates overtime (since reducing the PER values by a factor of ⅛ makes thosetransmission configurations more “attractive”). This may ensure that thehighest achievable DRSC is used during wireless transmission.

In 670, the update is completed.

Although the embodiments above have been described in considerabledetail, numerous variations and modifications will become apparent tothose skilled in the art once the above disclosure is fully appreciated.It is intended that the following claims be interpreted to embrace allsuch variations and modifications.

I claim:
 1. A method for performing wireless transmission of data over awireless communication medium, the method comprising: maintaining afirst data structure comprising data rate information for transmissionusing a first number of streams; maintaining a second data structurecomprising data rate information for transmission using a second numberof streams; determining channel characteristics of the wirelesscommunication medium; maintaining channel characteristic informationbased on the determined channel characteristics of the wirelesscommunication medium determining a stream configuration and data ratebased on the channel characteristic information, wherein saiddetermining the stream configuration comprises selecting either thefirst number of streams or the second number of streams; performingwireless transmission using the determined stream configuration and datarate; wherein said determining channel characteristics, maintainingchannel characteristic information, determining a stream configurationand data rate, and performing wireless transmission are dynamicallyperformed a plurality of times during wireless data transmission.
 2. Themethod of claim 1, wherein the first number of streams is
 1. 3. Themethod of claim 2, wherein the second number of streams is
 2. 4. Themethod of claim 1, wherein the channel characteristic informationcomprises a packet error rate.
 5. The method of claim 1, wherein saiddetermining channel characteristics of the wireless communication mediumcomprises sending one or more probe transmissions.
 6. The method ofclaim 1, wherein the first data structure and the second data structurecomprise first and second tables respectively, wherein each tablecomprises received signal strength indicators (RSSIs) and datamodulation information.
 7. The method of claim 1, wherein saiddetermining channel characteristics of the wireless communication mediumcomprises: transmitting one or more packets; and storing informationregarding the one or more packets, wherein the information comprisesacknowledgement information, received signal strength indicator (RSSI)information, and/or packet error rate (PER) information.
 8. The methodof claim 1, wherein said determining channel characteristics isperformed for every attempted transmission of packets.
 9. Anon-transitory computer accessible memory medium storing programinstructions for performing wireless transmission of data over awireless communication medium, wherein the program instructions areexecutable to: maintain a first data structure comprising data rateinformation for single stream transmission; maintain a second datastructure comprising data rate information for multiple streamtransmission; determine channel characteristics of the wirelesscommunication medium; maintain channel characteristic information basedon the determined channel characteristics of the wireless communicationmedium determine a stream configuration and data rate based on thechannel characteristic information, wherein said determining the streamconfiguration comprises selecting either single stream or multiplestream transmission; perform wireless transmission using the determinedstream configuration and data rate; wherein said determining channelcharacteristics, maintaining channel characteristic information,determining a stream configuration and data rate, and performingwireless transmission are dynamically performed a plurality of timesduring wireless data transmission.
 10. The non-transitory memory mediumof claim 9, wherein the channel characteristic information comprises apacket error rate.
 11. The non-transitory memory medium of claim 9,wherein said determining channel characteristics of the wirelesscommunication medium comprises sending one or more probe transmissions.12. The non-transitory memory medium of claim 9, wherein the first datastructure and the second data structure comprise first and second tablesrespectively, wherein each table comprises received signal strengthindicators (RSSIs) and data modulation information.
 13. Thenon-transitory memory medium of claim 9, wherein said determiningchannel characteristics of the wireless communication medium comprises:storing information regarding one or more transmitted packets, whereinthe information comprises acknowledgement information, received signalstrength indicator (RSSI) information, and/or packet error rate (PER)information.
 14. The non-transitory memory medium of claim 9, whereinsaid determining channel characteristics is performed for everyattempted transmission of packets.
 15. A wireless device, comprising: atransceiver; a processor coupled to the transceiver; and a memory mediumcoupled to the processor, wherein the memory medium stores: a first datastructure comprising data rate information for transmission using afirst number of streams; and a second data structure comprising datarate information for transmission using a second number of streams;wherein the memory medium also stores program instructions forperforming wireless transmission of data over a wireless communicationmedium, wherein the program instructions are executable by the processorto: determine channel characteristics of the wireless communicationmedium using the transceiver; maintain channel characteristicinformation based on the determined channel characteristics of thewireless communication medium; and determine a stream configuration anddata rate based on the channel characteristic information, wherein saiddetermining the stream configuration comprises selecting either thefirst number of streams or the second number of streams; wherein thetransceiver is configurable to perform wireless transmission using thedetermined stream configuration and data rate; wherein said determiningchannel characteristics, maintaining channel characteristic information,determining a stream configuration and data rate, and performingwireless transmission are dynamically performed a plurality of timesduring wireless data transmission.
 16. The wireless device of claim 15,wherein the first number of streams is
 1. 17. The wireless device ofclaim 15, wherein the second number of streams is
 2. 18. The wirelessdevice of claim 15, wherein the channel characteristic informationcomprises a packet error rate.
 19. The wireless device of claim 15,wherein said determining channel characteristics of the wirelesscommunication medium comprises sending one or more probe transmissions.20. The wireless device of claim 15, wherein the first data structureand the second data structure comprise first and second tablesrespectively, wherein each table comprises received signal strengthindicators (RSSIs) and data modulation information.
 21. The wirelessdevice of claim 15, wherein said determining channel characteristics ofthe wireless communication medium comprises: storing informationregarding one or more transmitted packets, wherein the informationcomprises acknowledgement information, received signal strengthindicator (RSSI) information, and/or packet error rate (PER)information.
 22. The wireless device of claim 15, wherein saiddetermining channel characteristics is performed for every attemptedtransmission of packets.